Observation of Quantized Conductance in Neutral Matter

TL;DR

This paper reports the first observation of quantized conductance in neutral, massive fermionic atoms, demonstrating a cold atom analog of mesoscopic electronic devices using light-shaped constrictions.

Contribution

It introduces a novel experimental realization of quantized conductance in neutral matter, extending mesoscopic physics to cold atom systems with high-resolution light potentials.

Findings

Quantized conductance plateaus observed in neutral fermionic lithium atoms.

Conductance quantum measured at 1/h, consistent with theoretical predictions.

Good agreement with the Landauer formula for low gate potentials.

Abstract

In transport experiments the quantum nature of matter becomes directly evident when changes in conductance occur only in discrete steps, with a size determined solely by Planck's constant h. The observations of quantized steps in the electric conductance have provided important insights into the physics of mesoscopic systems and allowed for the development of quantum electronic devices. Even though quantized conductance should not rely on the presence of electric charges, it has never been observed for neutral, massive particles. In its most fundamental form, the phenomenon requires a quantum degenerate Fermi gas, a ballistic and adiabatic transport channel, and a constriction with dimensions comparable to the Fermi wavelength. Here we report on the observation of quantized conductance in the transport of neutral atoms. We employ high resolution lithography to shape light potentials that realize either a quantum point contact or a quantum wire for atoms. These constrictions are imprinted on a quasi two-dimensional ballistic channel connecting two adjustable reservoirs of quantum degenerate fermionic lithium atoms. By tuning either a gate potential or the transverse confinement of the constrictions, we observe distinct plateaus in the conductance for atoms. The conductance in the first plateau is found to be equal to 1/h, the universal conductance quantum. For low gate potentials we find good agreement between the experimental data and the Landauer formula, with all parameters determined a priori. Our experiment constitutes the cold atom version of a mesoscopic device and can be readily extended to more complex geometries and interacting quantum gases.